DE10100968A1 - Device for removing flat objects - Google Patents

Abstract

A device for removing flat articles, in particular blanks of collapsed boxes from a delivery station and for transferring them to a receiving station which has a transport device thereat. Plural suction arms each with suction devices thereon are provided, which suction arms move through a self-contained cycloidal path. The cycloidal path has several tips and curved segments lying therebetween. The delivery station and the receiving station are each arranged at a tip of the cycloidal path. A rotor is provided for moving the suction arms. A sun and planet gear arrangement is provided on the rotor, which sun and planet gear delineate the cycloidal path. The suction arms are aligned parallel to one another and preferably to the transport direction of the transport device in order to achieve in this manner a technically simple and reliable device.

Description

The invention relates to a device for removing flat objects, in particular cuts of folding boxes from a delivery station and to Transfer this to a receiving station, which is a transport device for Has further transport of the objects, with several on one in itself closed cycloid orbital suction arms, each at least have a suction cup, the cycloidal path having several tips and in between has lying curves, the delivery station and the receiving station a tip of the cycloid track is arranged, and with one the suction arms moving rotor.

A device of this type is known from DE 40 29 520. It serves you individual removal of packaging blanks from a magazine and one Inserting these blanks into compartments on a conveyor belt. With this onset are the blanks by means of a control mechanism with a control curve by a Radial movement of the suction arms pressed away from the rotor into the compartments while doing so reshaped.

The known device has the disadvantage that the control mechanism is technically is relatively expensive. The invention is therefore based on the object Device of the type described above, but without a control mechanism create.

The problem is solved according to the characterizing part of claim 1. After that a planetary gear is provided on the rotor, which describes the cycloid orbit, and the suction cups are parallel to one another and preferably to the transport direction of the Transport device aligned.

The device according to the invention has the advantage that it is technically simpler Works wisely and without a control mechanism. The planetary gear is a conventional gearbox, which generates the cycloid orbit. The suckers are aligned parallel to each other and always remain in this direction during their Circulation. Thus, their connection to the planetary gear is easier Way feasible. The suction cups are attached to an object by the cyloid path brought up, then moved together with the object to the delivery station and finally put back on a subsequent item.  

Further advantageous embodiments of the invention are in claims 2 to 6 described.

An optimal use of the device over time is achieved if according to the Claims 2 and 3 on the device three or four suction arms or Sucker arm pairs are provided. Becomes an object from a pair of suction arms seized, its removal and onward transport are safer than if it were only to be moved by a single suction arm. Serve the same purpose also several suction cups on one suction arm.

If the rotor is driven continuously (claim 4), then a particularly high Item handover rate reached as rotor standstill avoided becomes. Servo technology can be used to handle the objects relevant peaks of the cyloid orbit the movement of the rotor is slowed down, to make handling even more reliable.

Flat folding box blanks can be removed from a magazine (claim 5) to erect them on a guide along the Cyloid Railway (Claim 6). The blanks are with a pre-folded edge on the Moved along the guide. The guide is adapted to the cycloid orbit in such a way that the distance between the cycloid trajectory as the blank is moved and the guide reduced so as to compress the blank and thereby the Erect folding box. The erected folding box is then attached to the Delivered transport device.

In the following, the invention will be illustrated by means of an exemplary embodiment Figures described in more detail. It shows:

Fig. 1 in a side view of a planetary gear on a rotor, three suction arms are each connected to a planet to move along a cycloid path, so that a blank for a folding box is removed from a magazine, erected on a guide and on a Delivery station is delivered to a transport device;

Fig. 2 in a sectional view the subject of Fig. 1, and

Fig. 3 shows a section along BB of Fig. 2 shows the object of Fig. 2.

The device contains a planetary gear 1 , which describes a four-arc cycloidal path Z, and further, superimposed gear stages 2 , 3 , which bring about a total transmission ratio of 1: 1 from the frame 4 to the suction arms 5 , so that on the one hand they describe a cycloidal path Z, simultaneously but always remain parallel to a straight line in frame 4 .

The planetary gear 1 consists of a rotor 6 which is fixedly connected to the drive shaft 7 and is mounted in the frame 4 . On the rotor 6 there are three planets 8 , which consist of the hollow shaft 9 , the spur gear 10 and the crank 11 . The spur gear 10 and the crank 11 are firmly connected to the hollow shaft 9 . In the planet 8 , the shafts 12 are mounted on which the suction arms 13 with the suction devices 14 are located.

A gear ratio from the spur gear 9 to the spur gear fixed to the frame with i = 4 is used to generate the four-armed cycloid, the intermediate gear 16 being mounted on the rotor 6 . The radius of the planet F is approximately 1: 3 to the radius of the rotor E.

In order to realize the parallelism of the suction cups 14 to the frame 4 , the gear stages 2 and 3 are superimposed on the planetary gear 1 . The gear stage 3 consists of a rotor 17 which is mounted eccentrically to the drive shaft 7 in the frame 4 , a shaft 19 which is mounted coaxially in the hollow shaft 9 and a crank 18 which is fixedly connected to the shaft 19 . In order to achieve a ratio of 1: 1 from the frame 4 to the shaft 19 , the eccentricity G must correspond to the crank radius H. The mode of operation thus corresponds to a "half" Schmidt coupling. The gear stage 2 consists of a spur gear 20 which is fixedly connected to the shaft 19 , a further spur gear 22 which is fixedly connected to the shaft 12 and an idler gear 21 which is mounted on the crank 11 . The number of teeth of the spur gears 20 and 22 must be identical.

If the suction arm 13 , which is part of a pair of suction arms, moves into the area of the tip A, a blank 34 is sucked out of the magazine 23 , and upon leaving the suction arm 13 of the tip A, this blank 34 is held by the suckers 14 and out of the Magazine 23 pulled over retaining lugs 24 . When passing through the arc from point A to point B, the edge 35 of the blank 34 facing away from the planetary gear 1 is guided along a guide 25 , so that the flat blank 34 straightens up to form a sleeve. Before the suction arm 5 reaches point B, the blank 34 is transferred to a rotating transport device 26 . The vacuum of the individual suction arms 5 is controlled mechanically by a circular arc segment embedded in the spur gear 15 . The air is sucked through suction bores 28 , 29 , 30 and a line 31 through the suction device 14 so that the blank 34 is sucked in.

It is particularly advantageous in the case of extraction and erection with this system that the blank 34 is kept parallel to the magazine 23 as well as to the transport device 26 at all times, so that even wider blanks 34 can be processed without problems. In addition, it is advantageous that when removing from the magazine 23 a movement in the direction of the magazine 23 is carried out almost exclusively, while the blank 34 already has a movement component in the transport direction when it is transferred to the transport device 26 .

Another advantage is that any number of planets 8 can be attached to the rotor 6 with suction arms 13 . This makes it z. B. possible to achieve a 33 percent increase in performance by increasing the number of suction arm pairs 27 from three to four, while the drive speed and thus the suction, erection and transfer time is the same as with three suction arm pairs 27 . A, B, C, D tip
E, F, radius
G eccentricity
H crank radius
Z cycloid orbit
1 planetary gear
2 , 3 gear stage
4 frames
5 suction arm
6 rotor
7 drive shaft
8 planet
9 hollow shaft
10 spur gear
11 crank
12 wave
13 suction arm
14 suction cups
15 spur gear
16 idler gear
17 rotor
18 crank
19 wave
20 spur gear
21 idler gear
22 spur gear
23 magazine
24 holding nose
25 leadership
26 Transport device
27 pair of suction arms
28 , 29 , 30 suction hole
31 line
34 cutting
35 edge
36 delivery station
37 receiving station
38 Transport direction

Claims (6)

1. Device for removing flat objects, in particular blanks ( 34 ) of folding boxes from a delivery station ( 36 ), and for transferring them to a receiving station ( 37 ), which has a transport device ( 26 ), with several on a self-contained cycloid track ( Z) revolving suction arms ( 13 ) with suction devices ( 14 ), the cycloidal path (Z) having a plurality of peaks (A, B, C, D) and intervening curves, the delivery station ( 36 ) and the receiving station ( 37 ) each a tip (A, B) of the cycloidal orbit (Z) is arranged, and with a rotor ( 6 ) moving the suction arms ( 13 ), characterized in that a planetary gear ( 1 ) is provided on the rotor ( 6 ) which drives the cycloidal orbit ( Z) describes that the suction arms ( 13 ) are aligned parallel to one another and preferably to the transport direction ( 38 ) of the transport device ( 26 ). 2. Device according to claim 1, characterized in that three or four suction arms ( 13 ) are provided on the device. 3. Device according to claim 1, characterized in that three or four pairs of suction arms ( 27 ) are provided on the device. 4. The device according to claim 1, claim 2 or claim 3, characterized in that the rotor ( 6 ) is continuously driven. 5. The device according to claim 1, claim 2, claim 3 or claim 4, characterized in that a magazine ( 23 ) is provided at the delivery station ( 36 ) for storing the flat objects. 6. The device according to at least one of claims 1 to 5, characterized in that along the cycloidal path (Z) between the delivery station ( 36 ) and the receiving station ( 37 ) a guide ( 25 ) is provided, along which an edge ( 35 ) of the Objects is moved along in order to deform the object, in particular to erect a blank ( 34 ) of a folding box.